/*---------------------------------------------------------------------------*\
  =========                 |
  \\      /  F ield         | OpenFOAM: The Open Source CFD Toolbox
   \\    /   O peration     |
    \\  /    A nd           | www.openfoam.com
     \\/     M anipulation  |
-------------------------------------------------------------------------------
    Copyright (C) 2011-2017 OpenFOAM Foundation
    Copyright (C) 2015-2020 OpenCFD Ltd.
-------------------------------------------------------------------------------
License
    This file is part of OpenFOAM.

    OpenFOAM is free software: you can redistribute it and/or modify it
    under the terms of the GNU General Public License as published by
    the Free Software Foundation, either version 3 of the License, or
    (at your option) any later version.

    OpenFOAM is distributed in the hope that it will be useful, but WITHOUT
    ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
    FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
    for more details.

    You should have received a copy of the GNU General Public License
    along with OpenFOAM.  If not, see <http://www.gnu.org/licenses/>.

Application
    redistributePar

Group
    grpParallelUtilities

Description
    Redistributes existing decomposed mesh and fields according to the current
    settings in the decomposeParDict file.

    Must be run on maximum number of source and destination processors.
    Balances mesh and writes new mesh to new time directory.

    Can optionally run in decompose/reconstruct mode to decompose/reconstruct
    mesh and fields.

Usage
    \b redistributePar [OPTION]

    Options:
      - \par -decompose
        Remove any existing \a processor subdirectories and decomposes the
        mesh. Equivalent to running without processor subdirectories.

      - \par -reconstruct
        Reconstruct mesh and fields (like reconstructParMesh+reconstructPar).

      - \par -newTimes
        (in combination with -reconstruct) reconstruct only new times.

      - \par -dry-run
        (not in combination with -reconstruct) Test without actually
        decomposing.

      - \par -cellDist
        not in combination with -reconstruct) Write the cell distribution
        as a labelList, for use with 'manual'
        decomposition method and as a volScalarField for visualization.

      - \par -region \<regionName\>
        Distribute named region.

      - \par -allRegions
        Distribute all regions in regionProperties. Does not check for
        existence of processor*.

\*---------------------------------------------------------------------------*/

#include "argList.H"
#include "sigFpe.H"
#include "Time.H"
#include "fvMesh.H"
#include "fvMeshTools.H"
#include "fvMeshDistribute.H"
#include "decompositionMethod.H"
#include "decompositionModel.H"
#include "timeSelector.H"
#include "PstreamReduceOps.H"
#include "volFields.H"
#include "surfaceFields.H"
#include "IOmapDistributePolyMesh.H"
#include "IOobjectList.H"
#include "globalIndex.H"
#include "loadOrCreateMesh.H"
#include "processorFvPatchField.H"
#include "zeroGradientFvPatchFields.H"
#include "topoSet.H"
#include "regionProperties.H"

#include "parFvFieldReconstructor.H"
#include "parLagrangianRedistributor.H"
#include "unmappedPassivePositionParticleCloud.H"
#include "hexRef8Data.H"
#include "meshRefinement.H"
#include "pointFields.H"

#include "cyclicACMIFvPatch.H"

using namespace Foam;

// * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * //

// Tolerance (as fraction of the bounding box). Needs to be fairly lax since
// usually meshes get written with limited precision (6 digits)
static const scalar defaultMergeTol = 1e-6;


// Get merging distance when matching face centres
scalar getMergeDistance
(
    const argList& args,
    const Time& runTime,
    const boundBox& bb
)
{
    const scalar mergeTol =
        args.getOrDefault<scalar>("mergeTol", defaultMergeTol);

    const scalar writeTol =
        Foam::pow(scalar(10), -scalar(IOstream::defaultPrecision()));

    Info<< "Merge tolerance : " << mergeTol << nl
        << "Write tolerance : " << writeTol << endl;

    if (runTime.writeFormat() == IOstream::ASCII && mergeTol < writeTol)
    {
        FatalErrorInFunction
            << "Your current settings specify ASCII writing with "
            << IOstream::defaultPrecision() << " digits precision." << nl
            << "Your merging tolerance (" << mergeTol << ") is finer than this."
            << nl
            << "Please change your writeFormat to binary"
            << " or increase the writePrecision" << endl
            << "or adjust the merge tolerance (-mergeTol)."
            << exit(FatalError);
    }

    const scalar mergeDist = mergeTol * bb.mag();

    Info<< "Overall meshes bounding box : " << bb << nl
        << "Relative tolerance          : " << mergeTol << nl
        << "Absolute matching distance  : " << mergeDist << nl
        << endl;

    return mergeDist;
}


void printMeshData(const polyMesh& mesh)
{
    // Collect all data on master

    globalIndex globalCells(mesh.nCells());
    labelListList patchNeiProcNo(Pstream::nProcs());
    labelListList patchSize(Pstream::nProcs());
    const labelList& pPatches = mesh.globalData().processorPatches();
    patchNeiProcNo[Pstream::myProcNo()].setSize(pPatches.size());
    patchSize[Pstream::myProcNo()].setSize(pPatches.size());
    forAll(pPatches, i)
    {
        const processorPolyPatch& ppp = refCast<const processorPolyPatch>
        (
            mesh.boundaryMesh()[pPatches[i]]
        );
        patchNeiProcNo[Pstream::myProcNo()][i] = ppp.neighbProcNo();
        patchSize[Pstream::myProcNo()][i] = ppp.size();
    }
    Pstream::gatherList(patchNeiProcNo);
    Pstream::gatherList(patchSize);


    // Print stats

    globalIndex globalBoundaryFaces(mesh.nBoundaryFaces());

    label maxProcCells = 0;
    label totProcFaces = 0;
    label maxProcPatches = 0;
    label totProcPatches = 0;
    label maxProcFaces = 0;

    for (label procI = 0; procI < Pstream::nProcs(); ++procI)
    {
        Info<< nl
            << "Processor " << procI << nl
            << "    Number of cells = " << globalCells.localSize(procI)
            << endl;

        label nProcFaces = 0;

        const labelList& nei = patchNeiProcNo[procI];

        forAll(patchNeiProcNo[procI], i)
        {
            Info<< "    Number of faces shared with processor "
                << patchNeiProcNo[procI][i] << " = " << patchSize[procI][i]
                << endl;

            nProcFaces += patchSize[procI][i];
        }

        Info<< "    Number of processor patches = " << nei.size() << nl
            << "    Number of processor faces = " << nProcFaces << nl
            << "    Number of boundary faces = "
            << globalBoundaryFaces.localSize(procI)-nProcFaces << endl;

        maxProcCells = max(maxProcCells, globalCells.localSize(procI));
        totProcFaces += nProcFaces;
        totProcPatches += nei.size();
        maxProcPatches = max(maxProcPatches, nei.size());
        maxProcFaces = max(maxProcFaces, nProcFaces);
    }

    // Stats

    scalar avgProcCells = scalar(globalCells.size())/Pstream::nProcs();
    scalar avgProcPatches = scalar(totProcPatches)/Pstream::nProcs();
    scalar avgProcFaces = scalar(totProcFaces)/Pstream::nProcs();

    // In case of all faces on one processor. Just to avoid division by 0.
    if (totProcPatches == 0)
    {
        avgProcPatches = 1;
    }
    if (totProcFaces == 0)
    {
        avgProcFaces = 1;
    }

    Info<< nl
        << "Number of processor faces = " << totProcFaces/2 << nl
        << "Max number of cells = " << maxProcCells
        << " (" << 100.0*(maxProcCells-avgProcCells)/avgProcCells
        << "% above average " << avgProcCells << ")" << nl
        << "Max number of processor patches = " << maxProcPatches
        << " (" << 100.0*(maxProcPatches-avgProcPatches)/avgProcPatches
        << "% above average " << avgProcPatches << ")" << nl
        << "Max number of faces between processors = " << maxProcFaces
        << " (" << 100.0*(maxProcFaces-avgProcFaces)/avgProcFaces
        << "% above average " << avgProcFaces << ")" << nl
        << endl;
}


// Debugging: write volScalarField with decomposition for post processing.
void writeDecomposition
(
    const word& name,
    const fvMesh& mesh,
    const labelUList& decomp
)
{
    // Write the decomposition as labelList for use with 'manual'
    // decomposition method.
    labelIOList cellDecomposition
    (
        IOobject
        (
            "cellDecomposition",
            mesh.facesInstance(),  // mesh read from facesInstance
            mesh,
            IOobject::NO_READ,
            IOobject::NO_WRITE,
            false
        ),
        decomp
    );
    cellDecomposition.write();

    Info<< "Writing wanted cell distribution to volScalarField " << name
        << " for postprocessing purposes." << nl << endl;

    volScalarField procCells
    (
        IOobject
        (
            name,
            mesh.time().timeName(),
            mesh,
            IOobject::NO_READ,
            IOobject::AUTO_WRITE,
            false                   // do not register
        ),
        mesh,
        dimensionedScalar(name, dimless, -1),
        zeroGradientFvPatchScalarField::typeName
    );

    forAll(procCells, cI)
    {
        procCells[cI] = decomp[cI];
    }

    procCells.correctBoundaryConditions();
    procCells.write();
}


void determineDecomposition
(
    const Time& baseRunTime,
    const fileName& decompDictFile, // optional location for decomposeParDict
    const bool decompose,       // decompose, i.e. read from undecomposed case
    const fileName& proc0CaseName,
    const fvMesh& mesh,
    const bool writeCellDist,

    label& nDestProcs,
    labelList& decomp
)
{
    // Read decomposeParDict (on all processors)
    const decompositionModel& method = decompositionModel::New
    (
        mesh,
        decompDictFile
    );

    decompositionMethod& decomposer = method.decomposer();

    if (!decomposer.parallelAware())
    {
        WarningInFunction
            << "You have selected decomposition method "
            << decomposer.typeName
            << " which does" << nl
            << "not synchronise the decomposition across"
            << " processor patches." << nl
            << "    You might want to select a decomposition method"
            << " which is aware of this. Continuing."
            << endl;
    }

    if (Pstream::master() && decompose)
    {
        Info<< "Setting caseName to " << baseRunTime.caseName()
            << " to read decomposeParDict" << endl;
        const_cast<Time&>(mesh.time()).caseName() = baseRunTime.caseName();
    }

    scalarField cellWeights;
    if (method.found("weightField"))
    {
        word weightName = method.get<word>("weightField");

        volScalarField weights
        (
            IOobject
            (
                weightName,
                mesh.time().timeName(),
                mesh,
                IOobject::MUST_READ,
                IOobject::NO_WRITE
            ),
            mesh
        );
        cellWeights = weights.internalField();
    }

    nDestProcs = decomposer.nDomains();
    decomp = decomposer.decompose(mesh, cellWeights);

    if (Pstream::master() && decompose)
    {
        Info<< "Restoring caseName to " << proc0CaseName << endl;
        const_cast<Time&>(mesh.time()).caseName() = proc0CaseName;
    }

    // Dump decomposition to volScalarField
    if (writeCellDist)
    {
        // Note: on master make sure to write to processor0
        if (decompose)
        {
            if (Pstream::master())
            {
                Info<< "Setting caseName to " << baseRunTime.caseName()
                    << " to write undecomposed cellDist" << endl;

                Time& tm = const_cast<Time&>(mesh.time());

                tm.caseName() = baseRunTime.caseName();
                writeDecomposition("cellDist", mesh, decomp);
                Info<< "Restoring caseName to " << proc0CaseName << endl;
                tm.caseName() = proc0CaseName;
            }
        }
        else
        {
            writeDecomposition("cellDist", mesh, decomp);
        }
    }
}


// Write addressing if decomposing (1 to many) or reconstructing (many to 1)
void writeProcAddressing
(
    const fvMesh& mesh,
    const mapDistributePolyMesh& map,
    const bool decompose
)
{
    Info<< "Writing procAddressing files to " << mesh.facesInstance()
        << endl;

    labelIOList cellMap
    (
        IOobject
        (
            "cellProcAddressing",
            mesh.facesInstance(),
            polyMesh::meshSubDir,
            mesh,
            IOobject::NO_READ
        ),
        0
    );

    labelIOList faceMap
    (
        IOobject
        (
            "faceProcAddressing",
            mesh.facesInstance(),
            polyMesh::meshSubDir,
            mesh,
            IOobject::NO_READ
        ),
        0
    );

    labelIOList pointMap
    (
        IOobject
        (
            "pointProcAddressing",
            mesh.facesInstance(),
            polyMesh::meshSubDir,
            mesh,
            IOobject::NO_READ
        ),
        0
    );

    labelIOList patchMap
    (
        IOobject
        (
            "boundaryProcAddressing",
            mesh.facesInstance(),
            polyMesh::meshSubDir,
            mesh,
            IOobject::NO_READ
        ),
        0
    );

    // Decomposing: see how cells moved from undecomposed case
    if (decompose)
    {
        cellMap = identity(map.nOldCells());
        map.distributeCellData(cellMap);

        faceMap = identity(map.nOldFaces());
        {
            const mapDistribute& faceDistMap = map.faceMap();

            if (faceDistMap.subHasFlip() || faceDistMap.constructHasFlip())
            {
                // Offset by 1
                faceMap = faceMap + 1;
            }
            // Apply face flips
            mapDistributeBase::distribute
            (
                Pstream::commsTypes::nonBlocking,
                List<labelPair>(),
                faceDistMap.constructSize(),
                faceDistMap.subMap(),
                faceDistMap.subHasFlip(),
                faceDistMap.constructMap(),
                faceDistMap.constructHasFlip(),
                faceMap,
                flipLabelOp()
            );
        }

        pointMap = identity(map.nOldPoints());
        map.distributePointData(pointMap);

        patchMap = identity(map.oldPatchSizes().size());
        const mapDistribute& patchDistMap = map.patchMap();
        // Use explicit distribute since we need to provide a null value
        // (for new patches) and this is the only call that allow us to
        // provide one ...
        mapDistributeBase::distribute
        (
            Pstream::commsTypes::nonBlocking,
            List<labelPair>(),
            patchDistMap.constructSize(),
            patchDistMap.subMap(),
            patchDistMap.subHasFlip(),
            patchDistMap.constructMap(),
            patchDistMap.constructHasFlip(),
            patchMap,
            eqOp<label>(),
            flipOp(),
            label(-1),
            UPstream::msgType()
        );
    }
    else    // reconstruct
    {
        cellMap = identity(mesh.nCells());
        map.cellMap().reverseDistribute(map.nOldCells(), cellMap);

        faceMap = identity(mesh.nFaces());
        {
            const mapDistribute& faceDistMap = map.faceMap();

            if (faceDistMap.subHasFlip() || faceDistMap.constructHasFlip())
            {
                // Offset by 1
                faceMap = faceMap + 1;
            }

            mapDistributeBase::distribute
            (
                Pstream::commsTypes::nonBlocking,
                List<labelPair>(),
                map.nOldFaces(),
                faceDistMap.constructMap(),
                faceDistMap.constructHasFlip(),
                faceDistMap.subMap(),
                faceDistMap.subHasFlip(),
                faceMap,
                flipLabelOp()
            );
        }

        pointMap = identity(mesh.nPoints());
        map.pointMap().reverseDistribute(map.nOldPoints(), pointMap);

        const mapDistribute& patchDistMap = map.patchMap();
        patchMap = identity(mesh.boundaryMesh().size());
        patchDistMap.reverseDistribute
        (
            map.oldPatchSizes().size(),
            label(-1),
            patchMap
        );
    }

    const bool cellOk = cellMap.write();
    const bool faceOk = faceMap.write();
    const bool pointOk = pointMap.write();
    const bool patchOk = patchMap.write();

    if (!cellOk || !faceOk || !pointOk || !patchOk)
    {
        WarningInFunction
            << "Failed to write " << cellMap.objectPath()
            << ", " << faceMap.objectPath()
            << ", " << pointMap.objectPath()
            << ", " << patchMap.objectPath()
            << endl;
    }
}


// Remove addressing
void removeProcAddressing(const polyMesh& mesh)
{
    for (const auto prefix : {"boundary", "cell", "face", "point"})
    {
        IOobject io
        (
            prefix + word("ProcAddressing"),
            mesh.facesInstance(),
            polyMesh::meshSubDir,
            mesh
        );

        const fileName procFile(io.objectPath());
        rm(procFile);
    }
}


// Generic mesh-based field reading
template<class GeoField>
void readField
(
    const IOobject& io,
    const fvMesh& mesh,
    const label i,
    PtrList<GeoField>& fields
)
{
    fields.set(i, new GeoField(io, mesh));
}


// Definition of readField for GeometricFields only
template<class Type, template<class> class PatchField, class GeoMesh>
void readField
(
    const IOobject& io,
    const fvMesh& mesh,
    const label i,
    PtrList<GeometricField<Type, PatchField, GeoMesh>>& fields
)
{
    fields.set
    (
        i,
        new GeometricField<Type, PatchField, GeoMesh>(io, mesh, false)
    );
}


// Read vol or surface fields
template<class GeoField>
void readFields
(
    const boolList& haveMesh,
    const fvMesh& mesh,
    const autoPtr<fvMeshSubset>& subsetterPtr,
    IOobjectList& allObjects,
    PtrList<GeoField>& fields
)
{
    // Get my objects of type
    IOobjectList objects(allObjects.lookupClass(GeoField::typeName));

    // Check that we all have all objects
    wordList objectNames = objects.sortedNames();

    // Get master names
    wordList masterNames(objectNames);
    Pstream::scatter(masterNames);

    if (haveMesh[Pstream::myProcNo()] && objectNames != masterNames)
    {
        FatalErrorInFunction
            << "Objects not synchronised across processors." << nl
            << "Master has " << flatOutput(masterNames) << nl
            << "Processor " << Pstream::myProcNo()
            << " has " << flatOutput(objectNames)
            << exit(FatalError);
    }

    fields.setSize(masterNames.size());

    // Have master send all fields to processors that don't have a mesh
    if (Pstream::master())
    {
        forAll(masterNames, i)
        {
            const word& name = masterNames[i];
            IOobject& io = *objects[name];
            io.writeOpt() = IOobject::AUTO_WRITE;

            // Load field (but not oldTime)
            readField(io, mesh, i, fields);
            // Create zero sized field and send
            if (subsetterPtr.valid())
            {
                tmp<GeoField> tsubfld = subsetterPtr().interpolate(fields[i]);

                // Send to all processors that don't have a mesh
                for (label procI = 1; procI < Pstream::nProcs(); ++procI)
                {
                    if (!haveMesh[procI])
                    {
                        OPstream toProc(Pstream::commsTypes::blocking, procI);
                        toProc<< tsubfld();
                    }
                }
            }
        }
    }
    else if (!haveMesh[Pstream::myProcNo()])
    {
        // Don't have mesh (nor fields). Receive empty field from master.

        forAll(masterNames, i)
        {
            const word& name = masterNames[i];

            // Receive field
            IPstream fromMaster
            (
                Pstream::commsTypes::blocking,
                Pstream::masterNo()
            );
            dictionary fieldDict(fromMaster);

            fields.set
            (
                i,
                new GeoField
                (
                    IOobject
                    (
                        name,
                        mesh.time().timeName(),
                        mesh,
                        IOobject::NO_READ,
                        IOobject::AUTO_WRITE
                    ),
                    mesh,
                    fieldDict
                )
            );

            //// Write it for next time round (since mesh gets written as well)
            //fields[i].write();
        }
    }
    else
    {
        // Have mesh so just try to load
        forAll(masterNames, i)
        {
            const word& name = masterNames[i];
            IOobject& io = *objects[name];
            io.writeOpt() = IOobject::AUTO_WRITE;

            // Load field (but not oldtime)
            readField(io, mesh, i, fields);
        }
    }
}


// Variant of GeometricField::correctBoundaryConditions that only
// evaluates selected patch fields
template<class GeoField, class CoupledPatchType>
void correctCoupledBoundaryConditions(fvMesh& mesh)
{
    HashTable<GeoField*> flds
    (
        mesh.objectRegistry::lookupClass<GeoField>()
    );

    forAllIters(flds, iter)
    {
        GeoField& fld = *iter();

        typename GeoField::Boundary& bfld = fld.boundaryFieldRef();
        if
        (
            Pstream::defaultCommsType == Pstream::commsTypes::blocking
         || Pstream::defaultCommsType == Pstream::commsTypes::nonBlocking
        )
        {
            const label nReq = Pstream::nRequests();

            forAll(bfld, patchi)
            {
                auto& pfld = bfld[patchi];
                const auto& fvp = mesh.boundary()[patchi];

                if (fvp.coupled() && !isA<cyclicACMIFvPatch>(fvp))
                {
                    pfld.initEvaluate(Pstream::defaultCommsType);
                }
            }

            // Block for any outstanding requests
            if
            (
                Pstream::parRun()
             && Pstream::defaultCommsType == Pstream::commsTypes::nonBlocking
            )
            {
                Pstream::waitRequests(nReq);
            }

            for (auto& pfld : bfld)
            {
                if (pfld.patch().coupled())
                {
                    pfld.evaluate(Pstream::defaultCommsType);
                }
            }
        }
        else if (Pstream::defaultCommsType == Pstream::commsTypes::scheduled)
        {
            const lduSchedule& patchSchedule =
                fld.mesh().globalData().patchSchedule();

            forAll(patchSchedule, patchEvali)
            {
                const label patchi = patchSchedule[patchEvali].patch;
                const auto& fvp = mesh.boundary()[patchi];
                auto& pfld = bfld[patchi];

                if (fvp.coupled() && !isA<cyclicACMIFvPatch>(fvp))
                {
                    if (patchSchedule[patchEvali].init)
                    {
                        pfld.initEvaluate(Pstream::commsTypes::scheduled);
                    }
                    else
                    {
                        pfld.evaluate(Pstream::commsTypes::scheduled);
                    }
                }
            }
        }
        else
        {
            FatalErrorInFunction
                << "Unsupported communications type "
                << Pstream::commsTypeNames[Pstream::defaultCommsType]
                << exit(FatalError);
        }
    }
}


// Inplace redistribute mesh and any fields
autoPtr<mapDistributePolyMesh> redistributeAndWrite
(
    const Time& baseRunTime,
    const scalar tolDim,
    const boolList& haveMesh,
    const fileName& meshSubDir,
    const bool doReadFields,
    const bool decompose,       // decompose, i.e. read from undecomposed case
    const bool reconstruct,
    const bool overwrite,
    const fileName& proc0CaseName,
    const label nDestProcs,
    const labelList& decomp,
    const fileName& masterInstDir,
    fvMesh& mesh
)
{
    Time& runTime = const_cast<Time&>(mesh.time());

    //// Print some statistics
    //Info<< "Before distribution:" << endl;
    //printMeshData(mesh);


    PtrList<volScalarField> volScalarFields;
    PtrList<volVectorField> volVectorFields;
    PtrList<volSphericalTensorField> volSphereTensorFields;
    PtrList<volSymmTensorField> volSymmTensorFields;
    PtrList<volTensorField> volTensorFields;

    PtrList<surfaceScalarField> surfScalarFields;
    PtrList<surfaceVectorField> surfVectorFields;
    PtrList<surfaceSphericalTensorField> surfSphereTensorFields;
    PtrList<surfaceSymmTensorField> surfSymmTensorFields;
    PtrList<surfaceTensorField> surfTensorFields;

    PtrList<DimensionedField<scalar, volMesh>> dimScalarFields;
    PtrList<DimensionedField<vector, volMesh>> dimVectorFields;
    PtrList<DimensionedField<sphericalTensor, volMesh>> dimSphereTensorFields;
    PtrList<DimensionedField<symmTensor, volMesh>> dimSymmTensorFields;
    PtrList<DimensionedField<tensor, volMesh>> dimTensorFields;

    DynamicList<word> pointFieldNames;


    if (doReadFields)
    {
        // Create 0 sized mesh to do all the generation of zero sized
        // fields on processors that have zero sized meshes. Note that this is
        // only necessary on master but since polyMesh construction with
        // Pstream::parRun does parallel comms we have to do it on all
        // processors
        autoPtr<fvMeshSubset> subsetterPtr;

        const bool allHaveMesh = !haveMesh.found(false);
        if (!allHaveMesh)
        {
            // Find last non-processor patch.
            const polyBoundaryMesh& patches = mesh.boundaryMesh();

            const label nonProcI = (patches.nNonProcessor() - 1);

            if (nonProcI < 0)
            {
                FatalErrorInFunction
                    << "Cannot find non-processor patch on processor "
                    << Pstream::myProcNo() << nl
                    << " Current patches:" << patches.names()
                    << abort(FatalError);
            }

            // Subset 0 cells, no parallel comms.
            // This is used to create zero-sized fields.
            subsetterPtr.reset
            (
                new fvMeshSubset(mesh, bitSet(), nonProcI, false)
            );
        }


        // Get original objects (before incrementing time!)
        if (Pstream::master() && decompose)
        {
            runTime.caseName() = baseRunTime.caseName();
        }
        IOobjectList objects(mesh, runTime.timeName());
        if (Pstream::master() && decompose)
        {
            runTime.caseName() = proc0CaseName;
        }

        Info<< "From time " << runTime.timeName()
            << " have objects:" << objects.names() << endl;

        // We don't want to map the decomposition (mapping already tested when
        // mapping the cell centre field)
        auto iter = objects.find("cellDist");
        if (iter.found())
        {
            objects.erase(iter);
        }


        // volFields

        if (Pstream::master() && decompose)
        {
            runTime.caseName() = baseRunTime.caseName();
        }
        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            volScalarFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            volVectorFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            volSphereTensorFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            volSymmTensorFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            volTensorFields
        );


        // surfaceFields

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            surfScalarFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            surfVectorFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            surfSphereTensorFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            surfSymmTensorFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            surfTensorFields
        );


        // Dimensioned internal fields
        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            dimScalarFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            dimVectorFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            dimSphereTensorFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            dimSymmTensorFields
        );

        readFields
        (
            haveMesh,
            mesh,
            subsetterPtr,
            objects,
            dimTensorFields
        );


        // pointFields currently not supported. Read their names so we
        // can delete them.
        {
            // Get my objects of type
            pointFieldNames.append
            (
                objects.lookupClass(pointScalarField::typeName).sortedNames()
            );
            pointFieldNames.append
            (
                objects.lookupClass(pointVectorField::typeName).sortedNames()
            );
            pointFieldNames.append
            (
                objects.lookupClass
                (
                    pointSphericalTensorField::typeName
                ).sortedNames()
            );
            pointFieldNames.append
            (
                objects.lookupClass
                (
                    pointSymmTensorField::typeName
                ).sortedNames()
            );
            pointFieldNames.append
            (
                objects.lookupClass(pointTensorField::typeName).sortedNames()
            );

            // Make sure all processors have the same set
            Pstream::scatter(pointFieldNames);
        }

        if (Pstream::master() && decompose)
        {
            runTime.caseName() = proc0CaseName;
        }
    }


    // Mesh distribution engine
    fvMeshDistribute distributor(mesh, tolDim);

    // Do all the distribution of mesh and fields
    autoPtr<mapDistributePolyMesh> rawMap = distributor.distribute(decomp);

    // Print some statistics
    Info<< "After distribution:" << endl;
    printMeshData(mesh);

    // Get other side of processor boundaries
    correctCoupledBoundaryConditions
    <
        volScalarField,
        processorFvPatchField<scalar>
    >(mesh);
    correctCoupledBoundaryConditions
    <
        volVectorField,
        processorFvPatchField<vector>
    >(mesh);
    correctCoupledBoundaryConditions
    <
        volSphericalTensorField,
        processorFvPatchField<sphericalTensor>
    >(mesh);
    correctCoupledBoundaryConditions
    <
        volSymmTensorField,
        processorFvPatchField<symmTensor>
    >(mesh);
    correctCoupledBoundaryConditions
    <
        volTensorField,
        processorFvPatchField<tensor>
    >(mesh);
    // No update surface fields


    // Set the minimum write precision
    IOstream::defaultPrecision(max(10u, IOstream::defaultPrecision()));


    if (!overwrite)
    {
        ++runTime;
        mesh.setInstance(runTime.timeName());
    }
    else
    {
        mesh.setInstance(masterInstDir);
    }


    IOmapDistributePolyMesh map
    (
        IOobject
        (
            "procAddressing",
            mesh.facesInstance(),
            polyMesh::meshSubDir,
            mesh,
            IOobject::NO_READ,
            IOobject::AUTO_WRITE
        )
    );
    map.transfer(rawMap());


    if (reconstruct)
    {
        if (Pstream::master())
        {
            Info<< "Setting caseName to " << baseRunTime.caseName()
                << " to write reconstructed mesh and fields." << endl;
            runTime.caseName() = baseRunTime.caseName();

            mesh.write();
            topoSet::removeFiles(mesh);
            for (const word& fieldName : pointFieldNames)
            {
                IOobject io
                (
                    fieldName,
                    runTime.timeName(),
                    mesh
                );

                const fileName fieldFile(io.objectPath());
                if (topoSet::debug) DebugVar(fieldFile);
                rm(fieldFile);
            }

            // Now we've written all. Reset caseName on master
            Info<< "Restoring caseName to " << proc0CaseName << endl;
            runTime.caseName() = proc0CaseName;
        }
    }
    else
    {
        mesh.write();
        topoSet::removeFiles(mesh);
        for (const word& fieldName : pointFieldNames)
        {
            IOobject io
            (
                fieldName,
                runTime.timeName(),
                mesh
            );

            const fileName fieldFile(io.objectPath());
            if (topoSet::debug) DebugVar(fieldFile);
            rm(fieldFile);
        }
    }
    Info<< "Written redistributed mesh to " << mesh.facesInstance() << nl
        << endl;


    if (decompose || reconstruct)
    {
        // Decompose (1 -> N) or reconstruct (N -> 1)
        // so {boundary,cell,face,point}ProcAddressing have meaning
        writeProcAddressing(mesh, map, decompose);
    }
    else
    {
        // Redistribute (N -> M)
        // {boundary,cell,face,point}ProcAddressing would be incorrect
        // - can either remove or redistribute previous
        removeProcAddressing(mesh);
    }


    // Refinement data
    {

        // Read refinement data
        if (Pstream::master() && decompose)
        {
            runTime.caseName() = baseRunTime.caseName();
        }
        IOobject io
        (
            "dummy",
            mesh.facesInstance(),
            polyMesh::meshSubDir,
            mesh,
            IOobject::READ_IF_PRESENT,
            IOobject::NO_WRITE,
            false
        );

        hexRef8Data refData(io);
        if (Pstream::master() && decompose)
        {
            runTime.caseName() = proc0CaseName;
        }

        // Make sure all processors have valid data (since only some will
        // read)
        refData.sync(io);

        // Distribute
        refData.distribute(map);


        // Now we've read refinement data we can remove it
        meshRefinement::removeFiles(mesh);

        if (reconstruct)
        {
            if (Pstream::master())
            {
                Info<< "Setting caseName to " << baseRunTime.caseName()
                    << " to write reconstructed refinement data." << endl;
                runTime.caseName() = baseRunTime.caseName();

                refData.write();

                // Now we've written all. Reset caseName on master
                Info<< "Restoring caseName to " << proc0CaseName << endl;
                runTime.caseName() = proc0CaseName;
            }
        }
        else
        {
            refData.write();
        }
    }

    //// Sets. Disabled for now.
    //{
    //    // Read sets
    //    if (Pstream::master() && decompose)
    //    {
    //        runTime.caseName() = baseRunTime.caseName();
    //    }
    //    IOobjectList objects(mesh, mesh.facesInstance(), "polyMesh/sets");
    //
    //    PtrList<cellSet> cellSets;
    //    ReadFields(objects, cellSets);
    //
    //    if (Pstream::master() && decompose)
    //    {
    //        runTime.caseName() = proc0CaseName;
    //    }
    //
    //    forAll(cellSets, i)
    //    {
    //        cellSets[i].distribute(map);
    //    }
    //
    //    if (reconstruct)
    //    {
    //        if (Pstream::master())
    //        {
    //            Info<< "Setting caseName to " << baseRunTime.caseName()
    //                << " to write reconstructed refinement data." << endl;
    //            runTime.caseName() = baseRunTime.caseName();
    //
    //            forAll(cellSets, i)
    //            {
    //                cellSets[i].distribute(map);
    //            }
    //
    //            // Now we've written all. Reset caseName on master
    //            Info<< "Restoring caseName to " << proc0CaseName << endl;
    //            runTime.caseName() = proc0CaseName;
    //        }
    //    }
    //    else
    //    {
    //        forAll(cellSets, i)
    //        {
    //            cellSets[i].distribute(map);
    //        }
    //    }
    //}


    return autoPtr<mapDistributePolyMesh>::New(std::move(map));
}


// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
//
// Field Mapping
//
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

autoPtr<mapDistributePolyMesh> createReconstructMap
(
    const autoPtr<fvMesh>& baseMeshPtr,
    const fvMesh& mesh,
    const labelList& cellProcAddressing,
    const labelList& faceProcAddressing,
    const labelList& pointProcAddressing,
    const labelList& boundaryProcAddressing
)
{
    // Send addressing to master
    labelListList cellAddressing(Pstream::nProcs());
    cellAddressing[Pstream::myProcNo()] = cellProcAddressing;
    Pstream::gatherList(cellAddressing);

    labelListList faceAddressing(Pstream::nProcs());
    faceAddressing[Pstream::myProcNo()] = faceProcAddressing;
    Pstream::gatherList(faceAddressing);

    labelListList pointAddressing(Pstream::nProcs());
    pointAddressing[Pstream::myProcNo()] = pointProcAddressing;
    Pstream::gatherList(pointAddressing);

    labelListList boundaryAddressing(Pstream::nProcs());
    {
        // Remove -1 entries
        DynamicList<label> patchProcAddressing(boundaryProcAddressing.size());
        forAll(boundaryProcAddressing, i)
        {
            if (boundaryProcAddressing[i] != -1)
            {
                patchProcAddressing.append(boundaryProcAddressing[i]);
            }
        }
        boundaryAddressing[Pstream::myProcNo()] = patchProcAddressing;
        Pstream::gatherList(boundaryAddressing);
    }


    autoPtr<mapDistributePolyMesh> mapPtr;

    if (baseMeshPtr.valid() && baseMeshPtr().nCells())
    {
        const fvMesh& baseMesh = baseMeshPtr();

        labelListList cellSubMap(Pstream::nProcs());
        cellSubMap[Pstream::masterNo()] = identity(mesh.nCells());

        mapDistribute cellMap
        (
            baseMesh.nCells(),
            std::move(cellSubMap),
            std::move(cellAddressing)
        );

        labelListList faceSubMap(Pstream::nProcs());
        faceSubMap[Pstream::masterNo()] = identity(mesh.nFaces());

        mapDistribute faceMap
        (
            baseMesh.nFaces(),
            std::move(faceSubMap),
            std::move(faceAddressing),
            false,          //subHasFlip
            true            //constructHasFlip
        );

        labelListList pointSubMap(Pstream::nProcs());
        pointSubMap[Pstream::masterNo()] = identity(mesh.nPoints());

        mapDistribute pointMap
        (
            baseMesh.nPoints(),
            std::move(pointSubMap),
            std::move(pointAddressing)
        );

        labelListList patchSubMap(Pstream::nProcs());
        // Send (filtered) patches to master
        patchSubMap[Pstream::masterNo()] =
            boundaryAddressing[Pstream::myProcNo()];

        mapDistribute patchMap
        (
            baseMesh.boundaryMesh().size(),
            std::move(patchSubMap),
            std::move(boundaryAddressing)
        );

        const label nOldPoints = mesh.nPoints();
        const label nOldFaces = mesh.nFaces();
        const label nOldCells = mesh.nCells();

        const polyBoundaryMesh& pbm = mesh.boundaryMesh();
        labelList oldPatchStarts(pbm.size());
        labelList oldPatchNMeshPoints(pbm.size());
        forAll(pbm, patchI)
        {
            oldPatchStarts[patchI] = pbm[patchI].start();
            oldPatchNMeshPoints[patchI] = pbm[patchI].nPoints();
        }

        mapPtr.reset
        (
            new mapDistributePolyMesh
            (
                nOldPoints,
                nOldFaces,
                nOldCells,
                std::move(oldPatchStarts),
                std::move(oldPatchNMeshPoints),
                std::move(pointMap),
                std::move(faceMap),
                std::move(cellMap),
                std::move(patchMap)
            )
        );
    }
    else
    {
        labelListList cellSubMap(Pstream::nProcs());
        cellSubMap[Pstream::masterNo()] = identity(mesh.nCells());
        labelListList cellConstructMap(Pstream::nProcs());

        mapDistribute cellMap
        (
            0,
            std::move(cellSubMap),
            std::move(cellConstructMap)
        );

        labelListList faceSubMap(Pstream::nProcs());
        faceSubMap[Pstream::masterNo()] = identity(mesh.nFaces());
        labelListList faceConstructMap(Pstream::nProcs());

        mapDistribute faceMap
        (
            0,
            std::move(faceSubMap),
            std::move(faceConstructMap),
            false,          //subHasFlip
            true            //constructHasFlip
        );

        labelListList pointSubMap(Pstream::nProcs());
        pointSubMap[Pstream::masterNo()] = identity(mesh.nPoints());
        labelListList pointConstructMap(Pstream::nProcs());

        mapDistribute pointMap
        (
            0,
            std::move(pointSubMap),
            std::move(pointConstructMap)
        );

        labelListList patchSubMap(Pstream::nProcs());
        // Send (filtered) patches to master
        patchSubMap[Pstream::masterNo()] =
            boundaryAddressing[Pstream::myProcNo()];
        labelListList patchConstructMap(Pstream::nProcs());

        mapDistribute patchMap
        (
            0,
            std::move(patchSubMap),
            std::move(patchConstructMap)
        );

        const label nOldPoints = mesh.nPoints();
        const label nOldFaces = mesh.nFaces();
        const label nOldCells = mesh.nCells();

        const polyBoundaryMesh& pbm = mesh.boundaryMesh();
        labelList oldPatchStarts(pbm.size());
        labelList oldPatchNMeshPoints(pbm.size());
        forAll(pbm, patchI)
        {
            oldPatchStarts[patchI] = pbm[patchI].start();
            oldPatchNMeshPoints[patchI] = pbm[patchI].nPoints();
        }

        mapPtr.reset
        (
            new mapDistributePolyMesh
            (
                nOldPoints,
                nOldFaces,
                nOldCells,
                std::move(oldPatchStarts),
                std::move(oldPatchNMeshPoints),
                std::move(pointMap),
                std::move(faceMap),
                std::move(cellMap),
                std::move(patchMap)
            )
        );
    }

    return mapPtr;
}


void readProcAddressing
(
    const fvMesh& mesh,
    const autoPtr<fvMesh>& baseMeshPtr,
    autoPtr<mapDistributePolyMesh>& distMap
)
{
    //IOobject io
    //(
    //    "procAddressing",
    //    mesh.facesInstance(),
    //    polyMesh::meshSubDir,
    //    mesh,
    //    IOobject::MUST_READ
    //);
    //if (io.typeHeaderOk<labelIOList>(true))
    //{
    //    Pout<< "Reading addressing from " << io.name() << " at "
    //        << mesh.facesInstance() << nl << endl;
    //    distMap.reset(new IOmapDistributePolyMesh(io));
    //}
    //else
    {
        Info<< "Reading addressing from procXXXAddressing at "
            << mesh.facesInstance() << nl << endl;
        labelIOList cellProcAddressing
        (
            IOobject
            (
                "cellProcAddressing",
                mesh.facesInstance(),
                polyMesh::meshSubDir,
                mesh,
                IOobject::READ_IF_PRESENT
            ),
            labelList()
        );
        labelIOList faceProcAddressing
        (
            IOobject
            (
                "faceProcAddressing",
                mesh.facesInstance(),
                polyMesh::meshSubDir,
                mesh,
                IOobject::READ_IF_PRESENT
            ),
            labelList()
        );
        labelIOList pointProcAddressing
        (
            IOobject
            (
                "pointProcAddressing",
                mesh.facesInstance(),
                polyMesh::meshSubDir,
                mesh,
                IOobject::READ_IF_PRESENT
            ),
            labelList()
        );
        labelIOList boundaryProcAddressing
        (
            IOobject
            (
                "boundaryProcAddressing",
                mesh.facesInstance(),
                polyMesh::meshSubDir,
                mesh,
                IOobject::READ_IF_PRESENT
            ),
            labelList()
        );


        if
        (
            mesh.nCells() != cellProcAddressing.size()
         || mesh.nPoints() != pointProcAddressing.size()
         || mesh.nFaces() != faceProcAddressing.size()
         || mesh.boundaryMesh().size() != boundaryProcAddressing.size()
        )
        {
            FatalErrorInFunction
                << "Read addressing inconsistent with mesh sizes" << nl
                << "cells:" << mesh.nCells()
                << " addressing:" << cellProcAddressing.objectPath()
                << " size:" << cellProcAddressing.size() << nl
                << "faces:" << mesh.nFaces()
                << " addressing:" << faceProcAddressing.objectPath()
                << " size:" << faceProcAddressing.size() << nl
                << "points:" << mesh.nPoints()
                << " addressing:" << pointProcAddressing.objectPath()
                << " size:" << pointProcAddressing.size()
                << "patches:" << mesh.boundaryMesh().size()
                << " addressing:" << boundaryProcAddressing.objectPath()
                << " size:" << boundaryProcAddressing.size()
                << exit(FatalError);
        }

        distMap.clear();
        distMap = createReconstructMap
        (
            baseMeshPtr,
            mesh,
            cellProcAddressing,
            faceProcAddressing,
            pointProcAddressing,
            boundaryProcAddressing
        );
    }
}


void reconstructMeshFields
(
    const parFvFieldReconstructor& fvReconstructor,
    const IOobjectList& objects,
    const wordRes& selectedFields
)
{
    // Dimensioned fields

    fvReconstructor.reconstructFvVolumeInternalFields<scalar>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvVolumeInternalFields<vector>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvVolumeInternalFields<sphericalTensor>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvVolumeInternalFields<symmTensor>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvVolumeInternalFields<tensor>
    (
        objects,
        selectedFields
    );


    // volFields

    fvReconstructor.reconstructFvVolumeFields<scalar>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvVolumeFields<vector>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvVolumeFields<sphericalTensor>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvVolumeFields<symmTensor>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvVolumeFields<tensor>
    (
        objects,
        selectedFields
    );


    // surfaceFields

    fvReconstructor.reconstructFvSurfaceFields<scalar>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvSurfaceFields<vector>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvSurfaceFields<sphericalTensor>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvSurfaceFields<symmTensor>
    (
        objects,
        selectedFields
    );
    fvReconstructor.reconstructFvSurfaceFields<tensor>
    (
        objects,
        selectedFields
    );
}


void reconstructLagrangian
(
    autoPtr<parLagrangianRedistributor>& lagrangianReconstructorPtr,
    const fvMesh& baseMesh,
    const fvMesh& mesh,
    const mapDistributePolyMesh& distMap,
    const wordRes& selectedLagrangianFields
)
{
    // Clouds (note: might not be present on all processors)

    wordList cloudNames;
    List<wordList> fieldNames;
    // Find all cloudNames on all processors
    parLagrangianRedistributor::findClouds(mesh, cloudNames, fieldNames);

    if (cloudNames.size())
    {
        if (!lagrangianReconstructorPtr.valid())
        {
            lagrangianReconstructorPtr.reset
            (
                new parLagrangianRedistributor
                (
                    mesh,
                    baseMesh,
                    mesh.nCells(),      // range of cell indices in clouds
                    distMap
                )
            );
        }
        const parLagrangianRedistributor& lagrangianReconstructor =
            *lagrangianReconstructorPtr;

        for (const word& cloudName : cloudNames)
        {
            Info<< "Reconstructing lagrangian fields for cloud "
                << cloudName << nl << endl;

            autoPtr<mapDistributeBase> lagrangianMapPtr =
                lagrangianReconstructor.redistributeLagrangianPositions
                (
                    cloudName
                );

            const mapDistributeBase& lagrangianMap = *lagrangianMapPtr;

            IOobjectList cloudObjs
            (
                mesh,
                mesh.time().timeName(),
                cloud::prefix/cloudName
            );

            lagrangianReconstructor.redistributeFields<label>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFieldFields<label>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFields<scalar>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFieldFields<scalar>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFields<vector>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFieldFields<vector>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFields
            <sphericalTensor>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFieldFields
            <sphericalTensor>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFields<symmTensor>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFieldFields
            <symmTensor>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFields<tensor>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
            lagrangianReconstructor.redistributeFieldFields<tensor>
            (
                lagrangianMap,
                cloudName,
                cloudObjs,
                selectedLagrangianFields
            );
        }
    }
}


// Read clouds (note: might not be present on all processors)
void readLagrangian
(
    const fvMesh& mesh,
    const wordList& cloudNames,
    const wordRes& selectedLagrangianFields,
    PtrList<unmappedPassivePositionParticleCloud>& clouds
)
{
    (void)mesh.tetBasePtIs();

    forAll(cloudNames, i)
    {
        //Pout<< "Loading cloud " << cloudNames[i] << endl;
        clouds.set
        (
            i,
            new unmappedPassivePositionParticleCloud(mesh, cloudNames[i], false)
        );


        //for (passivePositionParticle& p : clouds[i]))
        //{
        //    Pout<< "Particle position:" << p.position()
        //        << " cell:" << p.cell()
        //        << " with cc:" << mesh.cellCentres()[p.cell()]
        //        << endl;
        //}


        IOobjectList cloudObjs(clouds[i], clouds[i].time().timeName());

        //Pout<< "Found clould objects:" << cloudObjs.names() << endl;

        parLagrangianRedistributor::readFields
        <IOField<label>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <IOField<Field<label>>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <CompactIOField<Field<label>, label>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );


        parLagrangianRedistributor::readFields
        <IOField<scalar>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <IOField<Field<scalar>>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <CompactIOField<Field<scalar>, scalar>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );


        parLagrangianRedistributor::readFields
        <IOField<vector>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <IOField<Field<vector>>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <CompactIOField<Field<vector>, vector>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );


        parLagrangianRedistributor::readFields
        <IOField<sphericalTensor>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <IOField<Field<sphericalTensor>>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <CompactIOField<Field<sphericalTensor>, sphericalTensor>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );


        parLagrangianRedistributor::readFields
        <IOField<symmTensor>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <IOField<Field<symmTensor>>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <CompactIOField<Field<symmTensor>, symmTensor>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );


        parLagrangianRedistributor::readFields
        <IOField<tensor>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <IOField<Field<tensor>>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
        parLagrangianRedistributor::readFields
        <CompactIOField<Field<tensor>, tensor>>
        (
            clouds[i],
            cloudObjs,
            selectedLagrangianFields
        );
    }
}


void redistributeLagrangian
(
    autoPtr<parLagrangianRedistributor>& lagrangianReconstructorPtr,
    const fvMesh& mesh,
    const label nOldCells,
    const mapDistributePolyMesh& distMap,
    PtrList<unmappedPassivePositionParticleCloud>& clouds
)
{
    if (clouds.size())
    {
        if (!lagrangianReconstructorPtr.valid())
        {
            lagrangianReconstructorPtr.reset
            (
                new parLagrangianRedistributor
                (
                    mesh,
                    mesh,
                    nOldCells,  // range of cell indices in clouds
                    distMap
                )
            );
        }
        const parLagrangianRedistributor& distributor =
            lagrangianReconstructorPtr();

        forAll(clouds, i)
        {
            autoPtr<mapDistributeBase> lagrangianMapPtr =
                distributor.redistributeLagrangianPositions(clouds[i]);
            const mapDistributeBase& lagrangianMap = *lagrangianMapPtr;

            distributor.redistributeStoredFields
            <IOField<label>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <IOField<Field<label>>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <CompactIOField<Field<label>, label>>
            (
                lagrangianMap,
                clouds[i]
            );


            distributor.redistributeStoredFields
            <IOField<scalar>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <IOField<Field<scalar>>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <CompactIOField<Field<scalar>, scalar>>
            (
                lagrangianMap,
                clouds[i]
            );


            distributor.redistributeStoredFields
            <IOField<vector>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <IOField<Field<vector>>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <CompactIOField<Field<vector>, vector>>
            (
                lagrangianMap,
                clouds[i]
            );


            distributor.redistributeStoredFields
            <IOField<sphericalTensor>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <IOField<Field<sphericalTensor>>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <CompactIOField<Field<sphericalTensor>, sphericalTensor>>
            (
                lagrangianMap,
                clouds[i]
            );


            distributor.redistributeStoredFields
            <IOField<symmTensor>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <IOField<Field<symmTensor>>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <CompactIOField<Field<symmTensor>, symmTensor>>
            (
                lagrangianMap,
                clouds[i]
            );


            distributor.redistributeStoredFields
            <IOField<tensor>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <IOField<Field<tensor>>>
            (
                lagrangianMap,
                clouds[i]
            );
            distributor.redistributeStoredFields
            <CompactIOField<Field<tensor>, tensor>>
            (
                lagrangianMap,
                clouds[i]
            );
        }
    }
}


int main(int argc, char *argv[])
{
    argList::addNote
    (
        "Redistribute decomposed mesh and fields according"
        " to the decomposeParDict settings.\n"
        "Optionally run in decompose/reconstruct mode"
    );

    argList::noFunctionObjects();  // Never use function objects

    // enable -constant ... if someone really wants it
    // enable -zeroTime to prevent accidentally trashing the initial fields
    timeSelector::addOptions(true, true);
    #include "addRegionOption.H"
    argList::addBoolOption
    (
        "allRegions",
        "operate on all regions in regionProperties"
    );
    #include "addOverwriteOption.H"
    argList::addBoolOption("decompose", "Decompose case");
    argList::addBoolOption("reconstruct", "Reconstruct case");
    argList::addBoolOption
    (
        "dry-run",
        "Test without writing the decomposition. "
        "Changes -cellDist to only write volScalarField."
    );
    argList::addOption
    (
        "mergeTol",
        "scalar",
        "The merge distance relative to the bounding box size (default 1e-6)"
    );
    argList::addBoolOption
    (
        "cellDist",
        "Write cell distribution as a labelList - for use with 'manual' "
        "decomposition method or as a volScalarField for post-processing."
    );
    argList::addBoolOption
    (
        "newTimes",
        "Only reconstruct new times (i.e. that do not exist already)"
    );


    // Handle arguments
    // ~~~~~~~~~~~~~~~~
    // (replacement for setRootCase that does not abort)

    argList args(argc, argv);
    #include "foamDlOpenLibs.H"

    const bool reconstruct = args.found("reconstruct");
    const bool writeCellDist = args.found("cellDist");
    const bool dryrun = args.found("dry-run");
    const bool newTimes = args.found("newTimes");

    bool decompose = args.found("decompose");
    bool overwrite = args.found("overwrite");

    if (Foam::sigFpe::requested())
    {
        WarningInFunction
            << "Detected floating point exception trapping (FOAM_SIGFPE)."
            << " This might give" << nl
            << "    problems when mapping fields. Switch it off in case"
            << " of problems." << endl;
    }


    const wordRes selectedFields;
    const wordRes selectedLagrangianFields;


    if (decompose)
    {
        Info<< "Decomposing case (like decomposePar)" << nl << endl;
        if (reconstruct)
        {
            FatalErrorInFunction
                << "Cannot specify both -decompose and -reconstruct"
                << exit(FatalError);
        }
    }
    else if (reconstruct)
    {
        Info<< "Reconstructing case (like reconstructParMesh)" << nl << endl;
    }


    if (decompose || reconstruct)
    {
        if (!overwrite)
        {
            WarningInFunction
                << "Working in decompose or reconstruction mode automatically"
                << " implies -overwrite" << nl << endl;
            overwrite = true;
        }
    }


    if (!Pstream::parRun())
    {
        FatalErrorInFunction
            << ": This utility can only be run parallel"
            << exit(FatalError);
    }


    if (!isDir(args.rootPath()))
    {
        FatalErrorInFunction
            << ": cannot open root directory " << args.rootPath()
            << exit(FatalError);
    }

    // Detect if running data-distributed (multiple roots)
    bool nfs = true;
    {
        List<fileName> roots(1, args.rootPath());
        combineReduce(roots, ListOps::uniqueEqOp<fileName>());
        nfs = (roots.size() == 1);
    }

    if (!nfs)
    {
        Info<< "Detected multiple roots i.e. non-nfs running"
            << nl << endl;
    }

    if (isDir(args.path()))
    {
        if (decompose)
        {
            Info<< "Removing existing processor directories" << endl;
            rmDir(args.path());
        }
    }
    else
    {
        // Directory does not exist. If this happens on master -> decompose mode
        decompose = true;
        Info<< "No processor directories; switching on decompose mode"
            << nl << endl;
    }
    // If master changed to decompose mode make sure all nodes know about it
    Pstream::scatter(decompose);


    // If running distributed we have problem of new processors not finding
    // a system/controlDict. However if we switch on the master-only reading
    // the problem becomes that the time directories are differing sizes and
    // e.g. latestTime will pick up a different time (which causes createTime.H
    // to abort). So for now make sure to have master times on all
    // processors
    {
        Info<< "Creating time directories on all processors" << nl << endl;
        instantList timeDirs;
        if (Pstream::master())
        {
            const bool oldParRun = Pstream::parRun();
            Pstream::parRun() = false;
            timeDirs = Time::findTimes(args.path(), "constant");
            Pstream::parRun() = oldParRun;
        }
        Pstream::scatter(timeDirs);
        for (const instant& t : timeDirs)
        {
            mkDir(args.path()/t.name());
        }
    }


    // Construct time
    // ~~~~~~~~~~~~~~

    #include "createTime.H"
    runTime.functionObjects().off();  // Extra safety?


    // Save local processor0 casename
    const fileName proc0CaseName = runTime.caseName();


    // Construct undecomposed Time
    // ~~~~~~~~~~~~~~~~~~~~~~~~~~~
    // This will read the same controlDict but might have a different
    // set of times so enforce same times

    if (!nfs)
    {
        Info<< "Creating time directories for undecomposed Time"
            << " on all processors" << nl << endl;
        instantList timeDirs;

        const fileName basePath(args.globalPath());

        if (Pstream::master())
        {
            const bool oldParRun = Pstream::parRun();
            Pstream::parRun() = false;
            timeDirs = Time::findTimes(basePath, "constant");
            Pstream::parRun() = oldParRun;
        }
        Pstream::scatter(timeDirs);
        for (const instant& t : timeDirs)
        {
            mkDir(basePath/t.name());
        }
    }


    Info<< "Create undecomposed database"<< nl << endl;
    Time baseRunTime
    (
        runTime.controlDict(),
        runTime.rootPath(),
        runTime.globalCaseName(),
        runTime.system(),
        runTime.constant(),
        false                   // enableFunctionObjects
    );


    wordHashSet masterTimeDirSet;
    if (newTimes)
    {
        instantList baseTimeDirs(baseRunTime.times());
        for (const instant& t : baseTimeDirs)
        {
            masterTimeDirSet.insert(t.name());
        }
    }


    // Allow override of decomposeParDict location
    const fileName decompDictFile =
        args.getOrDefault<fileName>("decomposeParDict", "");

    // Get all region names
    wordList regionNames;
    if (args.found("allRegions"))
    {
        regionNames = regionProperties(runTime).names();

        Info<< "Decomposing all regions in regionProperties" << nl
            << "    " << flatOutput(regionNames) << nl << endl;
    }
    else
    {
        regionNames.resize(1);
        regionNames.first() =
            args.getOrDefault<word>("region", fvMesh::defaultRegion);
    }


    // Demand driven lagrangian mapper
    autoPtr<parLagrangianRedistributor> lagrangianReconstructorPtr;


    if (reconstruct)
    {
        // use the times list from the master processor
        // and select a subset based on the command-line options
        instantList timeDirs = timeSelector::select(runTime.times(), args);
        Pstream::scatter(timeDirs);

        if (timeDirs.empty())
        {
            FatalErrorInFunction
                << "No times selected"
                << exit(FatalError);
        }


        // Pass1 : reconstruct mesh and addressing
        // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~


        Info<< nl
            << "Pass1 : reconstructing mesh and addressing" << nl << endl;


        forAll(regionNames, regioni)
        {
            const word& regionName = regionNames[regioni];
            const fileName meshSubDir
            (
                regionName == fvMesh::defaultRegion
              ? fileName(polyMesh::meshSubDir)
              : regionNames[regioni]/polyMesh::meshSubDir
            );

            Info<< "\n\nReconstructing mesh " << regionName << nl << endl;

            // Loop over all times
            forAll(timeDirs, timeI)
            {
                // Set time for global database
                runTime.setTime(timeDirs[timeI], timeI);
                baseRunTime.setTime(timeDirs[timeI], timeI);

                Info<< "Time = " << runTime.timeName() << endl << endl;


                // See where the mesh is
                fileName facesInstance = runTime.findInstance
                (
                    meshSubDir,
                    "faces",
                    IOobject::READ_IF_PRESENT
                );
                //Pout<< "facesInstance:" << facesInstance << endl;

                Pstream::scatter(facesInstance);

                // Check who has a mesh
                const fileName meshPath =
                    runTime.path()/facesInstance/meshSubDir/"faces";

                Info<< "Checking for mesh in " << meshPath << nl << endl;

                boolList haveMesh(Pstream::nProcs(), false);
                haveMesh[Pstream::myProcNo()] = isFile(meshPath);
                Pstream::gatherList(haveMesh);
                Pstream::scatterList(haveMesh);
                Info<< "Per processor mesh availability:" << nl
                    << "    " << flatOutput(haveMesh) << nl << endl;


                // Addressing back to reconstructed mesh as xxxProcAddressing.
                // - all processors have consistent faceProcAddressing
                // - processors with no mesh don't need faceProcAddressing


                // Note: filePath searches up on processors that don't have
                //       processor if instance = constant so explicitly check
                //       found filename.
                bool haveAddressing = false;
                if (haveMesh[Pstream::myProcNo()])
                {
                    // Read faces (just to know their size)
                    faceCompactIOList faces
                    (
                        IOobject
                        (
                            "faces",
                            facesInstance,
                            meshSubDir,
                            runTime,
                            IOobject::MUST_READ
                        )
                    );

                    // Check faceProcAddressing
                    labelIOList faceProcAddressing
                    (
                        IOobject
                        (
                            "faceProcAddressing",
                            facesInstance,
                            meshSubDir,
                            runTime,
                            IOobject::READ_IF_PRESENT
                        ),
                        labelList()
                    );
                    if
                    (
                        faceProcAddressing.headerOk()
                     && faceProcAddressing.size() == faces.size()
                    )
                    {
                        haveAddressing = true;
                    }
                }
                else
                {
                    // Have no mesh. Don't need addressing
                    haveAddressing = true;
                }

                if (!returnReduce(haveAddressing, andOp<bool>()))
                {
                    Info<< "loading mesh from " << facesInstance << endl;
                    autoPtr<fvMesh> meshPtr = loadOrCreateMesh
                    (
                        IOobject
                        (
                            regionName,
                            facesInstance,
                            runTime,
                            Foam::IOobject::MUST_READ
                        )
                    );
                    fvMesh& mesh = meshPtr();

                    // Global matching tolerance
                    const scalar tolDim = getMergeDistance
                    (
                        args,
                        runTime,
                        mesh.bounds()
                    );


                    // Determine decomposition
                    // ~~~~~~~~~~~~~~~~~~~~~~~

                    Info<< "Reconstructing mesh for time " << facesInstance
                        << endl;

                    label nDestProcs = 1;
                    labelList finalDecomp = labelList(mesh.nCells(), Zero);

                    redistributeAndWrite
                    (
                        baseRunTime,
                        tolDim,
                        haveMesh,
                        meshSubDir,
                        false,      // do not read fields
                        false,      // do not read undecomposed case on proc0
                        true,       // write redistributed files to proc0
                        overwrite,
                        proc0CaseName,
                        nDestProcs,
                        finalDecomp,
                        facesInstance,
                        mesh
                    );
                }
            }


            // Pass2 : read mesh and addressing and reconstruct fields
            // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

            Info<< nl
                << "Pass2 : reconstructing fields" << nl << endl;

            runTime.setTime(timeDirs[0], 0);
            baseRunTime.setTime(timeDirs[0], 0);
            Info<< "Time = " << runTime.timeName() << endl << endl;


            Info<< "Reading undecomposed mesh (on master)" << endl;
            autoPtr<fvMesh> baseMeshPtr = fvMeshTools::newMesh
            (
                IOobject
                (
                    regionName,
                    baseRunTime.timeName(),
                    baseRunTime,
                    IOobject::MUST_READ
                ),
                true            // read on master only
            );

            Info<< "Reading local, decomposed mesh" << endl;
            autoPtr<fvMesh> meshPtr = loadOrCreateMesh
            (
                IOobject
                (
                    regionName,
                    baseMeshPtr().facesInstance(),
                    runTime,
                    Foam::IOobject::MUST_READ
                )
            );
            fvMesh& mesh = meshPtr();


            // Read addressing back to base mesh
            autoPtr<mapDistributePolyMesh> distMap;
            readProcAddressing(mesh, baseMeshPtr, distMap);

            // Construct field mapper
            autoPtr<parFvFieldReconstructor> fvReconstructorPtr
            (
                new parFvFieldReconstructor
                (
                    baseMeshPtr(),
                    mesh,
                    distMap(),
                    Pstream::master()       // do I need to write?
                )
            );



            // Since we start from Times[0] and not runTime.timeName() we
            // might overlook point motion in the first timestep
            // (since mesh.readUpdate() below will not be triggered). Instead
            // detect points by hand
            if (mesh.pointsInstance() != mesh.facesInstance())
            {
                Info<< "    Detected initial mesh motion;"
                    << " reconstructing points" << nl
                    << endl;
                fvReconstructorPtr().reconstructPoints();
            }


            // Loop over all times
            forAll(timeDirs, timeI)
            {
                if (newTimes && masterTimeDirSet.found(timeDirs[timeI].name()))
                {
                    Info<< "Skipping time " << timeDirs[timeI].name()
                        << endl << endl;
                    continue;
                }

                // Set time for global database
                runTime.setTime(timeDirs[timeI], timeI);
                baseRunTime.setTime(timeDirs[timeI], timeI);

                Info<< "Time = " << runTime.timeName() << endl << endl;


                // Check if any new meshes need to be read.
                fvMesh::readUpdateState procStat = mesh.readUpdate();

                if (procStat == fvMesh::POINTS_MOVED)
                {
                    Info<< "    Dected mesh motion; reconstructing points" << nl
                        << endl;
                    fvReconstructorPtr().reconstructPoints();
                }
                else if
                (
                    procStat == fvMesh::TOPO_CHANGE
                 || procStat == fvMesh::TOPO_PATCH_CHANGE
                )
                {
                    Info<< "    Detected topology change;"
                        << " reconstructing addressing" << nl << endl;

                    if (baseMeshPtr.valid())
                    {
                        // Cannot do a baseMesh::readUpdate() since not all
                        // processors will have mesh files. So instead just
                        // recreate baseMesh
                        baseMeshPtr.clear();
                        baseMeshPtr = fvMeshTools::newMesh
                        (
                            IOobject
                            (
                                regionName,
                                baseRunTime.timeName(),
                                baseRunTime,
                                IOobject::MUST_READ
                            ),
                            true            // read on master only
                        );
                    }

                    // Re-read procXXXaddressing
                    readProcAddressing(mesh, baseMeshPtr, distMap);

                    // Reset field mapper
                    fvReconstructorPtr.reset
                    (
                        new parFvFieldReconstructor
                        (
                            baseMeshPtr(),
                            mesh,
                            distMap(),
                            Pstream::master()
                        )
                    );
                    lagrangianReconstructorPtr.clear();
                }


                // Get list of objects
                IOobjectList objects(mesh, runTime.timeName());


                // Mesh fields (vol, surface, volInternal)
                reconstructMeshFields
                (
                    fvReconstructorPtr(),
                    objects,
                    selectedFields
                );

                // Clouds (note: might not be present on all processors)
                reconstructLagrangian
                (
                    lagrangianReconstructorPtr,
                    baseMeshPtr(),
                    mesh,
                    distMap(),
                    selectedLagrangianFields
                );

                // If there are any "uniform" directories copy them from
                // the master processor
                if (Pstream::master())
                {
                    fileName uniformDir0 = runTime.timePath()/"uniform";
                    if (isDir(uniformDir0))
                    {
                        Info<< "Detected additional non-decomposed files in "
                            << uniformDir0 << endl;
                        cp(uniformDir0, baseRunTime.timePath());
                    }
                }
            }
        }
    }
    else
    {
        // Time coming from processor0 (or undecomposed if no processor0)
        scalar masterTime;
        if (decompose)
        {
            // Use base time. This is to handle e.g. startTime = latestTime
            // which will not do anything if there are no processor directories
            masterTime = timeSelector::selectIfPresent
            (
                baseRunTime,
                args
            )[0].value();
        }
        else
        {
            masterTime = timeSelector::selectIfPresent
            (
                runTime,
                args
            )[0].value();
        }
        Pstream::scatter(masterTime);
        Info<< "Setting time to that of master or undecomposed case : "
            << masterTime << endl;
        runTime.setTime(masterTime, 0);



        forAll(regionNames, regioni)
        {
            const word& regionName = regionNames[regioni];
            const fileName meshSubDir
            (
                regionName == fvMesh::defaultRegion
              ? fileName(polyMesh::meshSubDir)
              : regionNames[regioni]/polyMesh::meshSubDir
            );

            if (decompose)
            {
                Info<< "\n\nDecomposing mesh " << regionName << nl << endl;
            }
            else
            {
                Info<< "\n\nRedistributing mesh " << regionName << nl << endl;
            }


            // Get time instance directory
            // ~~~~~~~~~~~~~~~~~~~~~~~~~~~
            // At this point we should be able to read at least a mesh on
            // processor0. Note the changing of the processor0 casename to
            // enforce it to read/write from the undecomposed case

            fileName masterInstDir;
            if (Pstream::master())
            {
                if (decompose)
                {
                    Info<< "Setting caseName to " << baseRunTime.caseName()
                        << " to find undecomposed mesh" << endl;
                    runTime.caseName() = baseRunTime.caseName();
                }

                masterInstDir = runTime.findInstance
                (
                    meshSubDir,
                    "faces",
                    IOobject::READ_IF_PRESENT
                );

                if (decompose)
                {
                    Info<< "Restoring caseName to " << proc0CaseName << endl;
                    runTime.caseName() = proc0CaseName;
                }
            }
            Pstream::scatter(masterInstDir);

            // Check who has a mesh
            const fileName meshPath =
                runTime.path()/masterInstDir/meshSubDir/"faces";

            Info<< "Checking for mesh in " << meshPath << nl << endl;


            boolList haveMesh(Pstream::nProcs(), false);
            haveMesh[Pstream::myProcNo()] = isFile(meshPath);
            Pstream::gatherList(haveMesh);
            Pstream::scatterList(haveMesh);
            Info<< "Per processor mesh availability:" << nl
                << "    " << flatOutput(haveMesh) << nl << endl;

            // Load mesh (or create dummy one)
            // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~

            if (Pstream::master() && decompose)
            {
                Info<< "Setting caseName to " << baseRunTime.caseName()
                    << " to read undecomposed mesh" << endl;
                runTime.caseName() = baseRunTime.caseName();
            }

            autoPtr<fvMesh> meshPtr = loadOrCreateMesh
            (
                IOobject
                (
                    regionName,
                    masterInstDir,
                    runTime,
                    Foam::IOobject::MUST_READ
                )
            );

            if (Pstream::master() && decompose)
            {
                Info<< "Restoring caseName to " << proc0CaseName << endl;
                runTime.caseName() = proc0CaseName;
            }

            fvMesh& mesh = meshPtr();


            const label nOldCells = mesh.nCells();
            //Pout<< "Loaded mesh : nCells:" << nOldCells
            //    << " nPatches:" << mesh.boundaryMesh().size() << endl;


            // Global matching tolerance
            const scalar tolDim = getMergeDistance
            (
                args,
                runTime,
                mesh.bounds()
            );

            // Determine decomposition
            // ~~~~~~~~~~~~~~~~~~~~~~~

            label nDestProcs;
            labelList finalDecomp;
            determineDecomposition
            (
                baseRunTime,
                decompDictFile,
                decompose,
                proc0CaseName,
                mesh,
                writeCellDist,

                nDestProcs,
                finalDecomp
            );

            if (dryrun)
            {
                if (!Pstream::master() && !haveMesh[Pstream::myProcNo()])
                {
                    // Remove dummy mesh created by loadOrCreateMesh
                    const bool oldParRun = Pstream::parRun();
                    Pstream::parRun() = false;
                    mesh.removeFiles();
                    rmDir(mesh.objectRegistry::objectPath());
                    Pstream::parRun() = oldParRun;
                }
                continue;
            }



            wordList cloudNames;
            List<wordList> fieldNames;

            // Detect lagrangian fields
            if (Pstream::master() && decompose)
            {
                runTime.caseName() = baseRunTime.caseName();
            }
            parLagrangianRedistributor::findClouds
            (
                mesh,
                cloudNames,
                fieldNames
            );

            // Read lagrangian fields and store on cloud (objectRegistry)
            PtrList<unmappedPassivePositionParticleCloud> clouds
            (
                cloudNames.size()
            );
            readLagrangian
            (
                mesh,
                cloudNames,
                selectedLagrangianFields,
                clouds
            );
            if (Pstream::master() && decompose)
            {
                runTime.caseName() = proc0CaseName;
            }


            // Load fields, do all distribution (mesh and fields - but not
            // lagrangian fields; these are done later)
            autoPtr<mapDistributePolyMesh> distMap = redistributeAndWrite
            (
                baseRunTime,
                tolDim,
                haveMesh,
                meshSubDir,
                true,           // read fields
                decompose,      // decompose, i.e. read from undecomposed case
                false,          // no reconstruction
                overwrite,
                proc0CaseName,
                nDestProcs,
                finalDecomp,
                masterInstDir,
                mesh
            );


            // Redistribute any clouds
            redistributeLagrangian
            (
                lagrangianReconstructorPtr,
                mesh,
                nOldCells,
                distMap(),
                clouds
            );


            // Copy any uniform data
            const fileName uniformDir("uniform");
            if (isDir(baseRunTime.timePath()/uniformDir))
            {
                Info<< "Detected additional non-decomposed files in "
                    << baseRunTime.timePath()/uniformDir << endl;
                cp
                (
                    baseRunTime.timePath()/uniformDir,
                    runTime.timePath()/uniformDir
                );
            }
        }
    }


    Info<< "End\n" << endl;

    return 0;
}


// ************************************************************************* //
